CN102897574B - Sheet stacking apparatus and image forming apparatus - Google Patents

Abstract

There are provided a sheet stacking apparatus capable of stably stacking a large number of sheets and an image forming apparatus. The sheet stacking apparatus configured to stack sheets includes a plurality of discharge units disposed to an apparatus main body in a vertical direction and configured to discharge sheets, a plurality of sheet stacking units disposed to be independently elevatable on a side surface of the apparatus main body corresponding respectively to the plurality of discharge units and configured to stack thereon the sheets discharged from the discharge units, and an alignment unit disposed between the plurality of sheet stacking units and configured to sequentially align a position in a width direction perpendicular to a discharging direction of the sheets stacked on a lower sheet stacking unit among the plurality of sheet stacking units.

Description

Sheet-stacking apparatus and imaging device

Technical field

Present disclosure relates to sheet-stacking apparatus and imaging device, and described sheet-stacking apparatus stackingly can will be discharged to a large amount of sheet materials on it.

Background technology

Image taking speed for the imaging device of imaging on sheet material is accelerated along with technological advance recently.The quickening of this image taking speed caused the discharge velocity of sheet material that will discharge from imaging device body accelerate.Japanese Patent Application Laid-Open No.2007-062907 describes a kind of imaging device with sheet-stacking apparatus, and this sheet-stacking apparatus is for aliging and stacking a large amount of sheet materials of discharging with high speed.

According to Japanese Patent Application Laid-Open No.2007-062907, sheet-stacking apparatus has multiple discharge orifice and corresponding with multiple discharge orifice and can the heap tray of independent-lifting.When sheet-stacking is in this heap tray, along with stacking sheet material quantity increases, this heap tray moves down, thus can increase the sheet material quantity be stacked on pallet.

Have multiple heap tray to increase in the existing sheet-stacking apparatus of the sheet material quantity that will be stacked thereon this, more sheet material is configured to be stacked in the heap tray of below, to strengthen the stability of this sheet-stacking apparatus.Have sheet material more more than the heap tray of top due to stacking in the heap tray of below, so when the sheet material of stacking maximum quantity, the center of gravity of whole sheet-stacking apparatus is positioned at below.Thereby, it is possible to improve the stability of sheet-stacking apparatus.

But, when a large amount of sheet-stackings is in the heap tray of below, exist heap tray can stacking performance decline thus stable sheet-stacking become difficulty situation.

Summary of the invention

Present disclosure relates to sheet-stacking apparatus and imaging device, can stably stacking a large amount of sheet material on described sheet-stacking apparatus.

According to the one side of the present embodiment disclosed herein, sheet-stacking apparatus comprises: multiple deliverying units vertically, construct to discharge sheet material; Multiple separate sheet-stacking unit, relative to the respective deliverying unit liftable in described multiple deliverying unit, and structure in order to thereon stacking from deliverying unit discharge sheet material; And alignment unit, be located between described multiple sheet-stacking unit, and structure is in order to make to be discharged to the aligned in position of the sheet material on the below sheet-stacking unit in described multiple sheet-stacking unit at the Width vertical with discharge direction.

According to present disclosure, alignment unit is located between described multiple liftable sheet-stacking unit, and described alignment unit makes the sheet material be stacked on the below sheet-stacking unit in described multiple sheet-stacking unit align in turn in the position of Width.Thus, a large amount of sheet material can be stably stacking.

By referring to the detailed description of accompanying drawing to example embodiment, the further feature of present disclosure and aspect will become obvious.

Accompanying drawing explanation

Comprise in the description and the accompanying drawing of a part forming specification sheets represents example embodiment, the characteristic sum aspect of disclosure, and be used from following explanation one and explain principle disclosed herein.

Fig. 1 represents according to the first example embodiment as the diagram of structure of monochrome/color copy machine of an example of imaging device with sheet-stacking apparatus.

Fig. 2 is the diagram of the structure representing sheet-stacking apparatus.

Fig. 3 A, 3B and 3C are the first figure of the structure representing the pallet alignment unit be located in sheet-stacking apparatus.

Fig. 4 A and 4B is the second figure of the structure representing pallet alignment unit.

Fig. 5 A and 5B is the 3rd figure of the structure representing pallet alignment unit.

Fig. 6 A, 6B and 6C are the 4th figure of the structure representing pallet alignment unit.

Fig. 7 is the 5th figure of the structure representing pallet alignment unit.

Fig. 8 A and 8B is the first figure of the lifting mechanism represented for each upper and lower pallet be located on sheet-stacking apparatus.

Fig. 9 is the second figure of the lifting mechanism represented for each upper and lower pallet.

Figure 10 represents to be located at the diagram of the upper and lower supporter disc material on upper and lower pallet with or without detecting sensor respectively.

Figure 11 is the control block diagram of monochrome/color copy machine.

Figure 12 is the control block diagram of the sheet-stacking apparatus control unit for controlling sheet-stacking apparatus.

Figure 13 illustrates the diagram of circuit controlled the retreating position of the align unit be located in pallet alignment unit.

Figure 14 A, 14B and 14C are all the diagrams representing relation between the position of top tray and the retreating position of align unit.

Figure 15 A, 15B and 15C represent that align unit moves down along with top tray and the diagram of the state moved down.

Figure 16 is the diagram of circuit representing the position control controlled the retreating position of the align unit be located in pallet alignment unit according to the second example embodiment and to the lower tray of sheet-stacking apparatus.

Figure 17 A and 17B be all represent when taking out stacking sheet material from lower tray align unit, the diagram of position relationship between lower tray and top tray.

Figure 18 A and 18B be all represent when taking out stacking sheet material from top tray align unit, the diagram of position relationship between lower tray and top tray.

Detailed description of the invention

Comprise in the description and the accompanying drawing of a part forming specification sheets represents example embodiment of the present invention, characteristic sum aspect, and be used from following explanation one and explain principle disclosed herein.

Fig. 1 represents according to the first example embodiment as the diagram of structure of monochrome/color copy machine of an example of imaging device with sheet-stacking apparatus.As shown in Figure 1, monochrome/color copy machine 100 comprises monochrome/color copy machine body (hereinafter referred to as copying machine body) 100A.

Copying machine body 100A comprises sheet feeding box 101a and 101b, as the image-generating unit 100B of imaging device and fixation unit 103.Each sheet feeding box 101a and 101b is stacked into picture sheet material P thereon.Image-generating unit 100B adopts electrofax process to form toner image on sheet material.The toner image that the fixing sheet material of fixation unit 103 is formed.

Operating unit 601 is connected with the upper surface of copying machine body 100A, and sheet-stacking apparatus 500 is connected with the side of copying machine body 100A.User uses operating unit 601 couples of copying machine body 100A to carry out various input or setting.Sheet-stacking apparatus 500 can be used as selection equipment, and therefore copying machine body 100A also can be used alone.

Sheet-stacking apparatus 500 and copying machine body 100A can integrations.Central processing unit (CPU) circuit unit 630 is the control setups for controlling copying machine body 100A and sheet-stacking apparatus 500.

When utilizing this monochrome/color copy machine 100 imaging, first yellow, pinkish red, blue or green, black four colour toners images are formed on the respective photosensitive drums 102a to 102d that is located in image-generating unit 100B.

Then, toner image is transferred to from the sheet material of sheet feeding box 101a and 101b supply.Subsequently, the toner image be transferred on sheet material is fixing by fixation unit 103.If perform imaging with the pattern of imaging in sheet material one side, then, after toner image, sheet material is expelled to 104 the sheet-stacking apparatus 500 be connected with the side of copying machine body 100A from distributing roller.

If perform imaging with the pattern of imaging on sheet material two sides, then sheet material is supplied to reverse roll 105 from fixation unit 103.Then, reverse roll 105 reverses, sheet material is sent to the direction of two-sided transfer roller 106a to 106f in predetermined timing.

Subsequently, sheet material is transferred into image-generating unit 100B again, and yellow, pinkish red, blue or green, black four colour toners images are transferred on the back side of sheet material.Then, four colour toners image transfer printings sheet material is thereon transferred into fixation unit 103 again, makes the toner image on the back side.Then, sheet material to be discharged 104 from distributing roller and is sent to sheet-stacking apparatus 500.

Sheet-stacking apparatus 500 receives the sheet material of discharging from copying machine body 100A in turn, and makes this sheet-stacking in the top tray 515 be located at as sheet material stacking apparatus on the side of apparatus body 500A and lower tray 516 on any one.

This two pallet 515 and 516 suitably uses according to situation.Such as, user can select top tray 515 or lower tray 516 according to the output during the output of duplicating under output, printer output, sample output, interrupt output, heap tray overload situations, Function Classification output and mixture operation.

As shown in Figure 2, sheet-stacking apparatus 500 to comprise for receiver sheet to the entrance roller of apparatus body 500A inside 501.The sheet material of discharging from copying machine body 100A is provided to entrance roller to 501.Then, entrance roller is utilized to be sent to buffer roll to 508 from transfer roller to 502 to 507 in turn to the sheet material that 501 transmit.

When sheet material is discharged in top tray 515, this upper pathway switching part 509 of the driver element (not shown) of such as screw actuator one class is utilized to be switched from the initial position of upper pathway switching part 509.Thus, sheet material is expelled to top tray 515 by upper distributing roller 510 from upper discharge orifice 500B.Upper discharge orifice 500B is as the eduction gear be vertically located in copying machine body 100A, and top tray 515 corresponds to upper discharge orifice 500B.

When sheet material is discharged in lower tray 516, by stopping driver element, upper pathway switching part 509 returns initial position.Thus, sheet material is sent to transfer roller to 511 to 513 by upper pathway switching part 509, and is expelled to lower tray 516 by lower distributing roller 514 from lower discharge orifice 500C.Sheet-stacking is in the lower tray 516 corresponding with the lower discharge orifice 500C as eduction gear.

Thus, the sheet material of discharging from copying machine body 100A is received by sheet-stacking apparatus 500 in turn, and is stacked in top tray 515 and lower tray 516.

Top tray alignment unit 517 as aligning apparatus is located at the top of top tray 515.Top tray alignment unit 517 alignment is stacked on the width position perpendicular with sheet material discharge direction of the sheet material in top tray 515.

In addition, the top of lower tray 516 is located at as the lower tray alignment unit 518 of aligning apparatus.Lower tray alignment unit 518 alignment is stacked on the width position of the sheet material in lower tray 516.

Fig. 3 A, 3B and 3C are all the diagrams of the structure representing the lower tray alignment unit 518 being discharged to the sheet material in lower tray 516 for aliging.As shown in figs.3 a and 3b, lower tray alignment unit 518 comprises the align unit 519 for the discharged sheet material that aligns.Align unit 519 is located on the every side in the side, front and back of the Width of sheet-stacking apparatus 500, that is, align unit 519 is located in both end sides, described with reference to Figure 5.

Align unit 519 can be supported by the first alignment fulcrum 520 by the vertical direction rotationally, and slides along the first alignment fulcrum 520 via the slide unit 521 slided along the first alignment fulcrum 520.

The second alignment fulcrum 522 as rotational stop inserts in slide unit 521.As described below, when align unit 519 rotates around the first alignment fulcrum 520 in the vertical direction, the rotation of the second alignment fulcrum 522 limit slippage parts 521.

As shown in Figure 3 C, the second slip driving band 525 is sandwiched between slide unit 521 and sliding position detection part 523.

When the second slip driving band 525 rotates, sliding position detection part 523 and slide unit 521 slide, and align unit 519 slides along with the slip of this slide unit 521.

This slip of sliding position detection part 523 utilizes rear align unit initial position (HP) the sensor S1 shown in Fig. 5 B to detect, can detect align unit 519(slide unit 521) move to slip HP.

Second slip driving band 525 is wound on slip driven pulley 526a and 526b.Slip driven pulley 526a is cone pulley as shown in Figure 4 A.Second slip driving band 525 and the first slip driving band 524 are wound on slip driven pulley 526a.First slip driving band 524 is rotated by rear align unit sliding motor M1.

Therefore, when rear align unit sliding motor M1 rotates, this rotation passes to slide unit 521 via the first slip driving band 524, slip driven pulley 526a and the second slip driving band 525.Thus, align unit 519 and slide unit 521 broad ways (fore-and-aft direction) while one guides by the first alignment fulcrum 520 is mobile.

As shown in Figure 4 A, slip driven pulley 526a is supported by the pulley fulcrum 527 of riveting with pulley mounted panel 528.The two ends of the first alignment fulcrum 520 and the second alignment fulcrum 522 utilize the environmental protection of E type to be held on pulley mounted panel 528.

Align unit 519, pulley mounted panel 528 and other parts form a unit under state as illustrated in figures 4 a and 4b, and are attached to as shown in Figure 5A on the rear side of support 529.In addition, rear align unit sliding motor M1 is attached to via slip drive motor mounted panel 530 on the rear side of upper support 529 as shown in Figure 5 B.

The front side of the upper support 529 of lower tray alignment unit 518 comprises the attaching unit be made up of align unit 519, pulley mounted panel 528 and other parts thereon and front align unit sliding motor M2, and the structure of this unit is identical with the unit structure on the rear side being attached to upper support 529.

As shown in Figure 5 B, rear align unit HP sensor S1 detects together with mounted panel 531 with aligned position and is attached on upper support 529.Rear align unit HP sensor S1 detects the position of the rear side align unit 519 on rear side by the position detecting sliding position detection part 523.

Front align unit HP sensor S2 detects together with mounted panel 531 with aligned position and is attached on upper support 529.Front align unit HP sensor S2 detects the position of the align unit 519 on front side.

These align units 519 on rear side and front side in pairs and broad ways slide, thus the sheet material that alignment is discharged in lower tray 516.Such as, when sheet material is discharged in lower tray 516, the align unit 519 on side, front and back is made to move to respective aligned position according to sheets of sizes from the slip of its initial position, thus the width position of alignment sheet material.

In addition, as Fig. 6 A, shown in 6B and 6C, the 3rd fulcrum 532 inserts align unit 519 and is located in the guide groove 521a of slide unit 521 bottom.Here, the two ends of the 3rd fulcrum 532 are chimeric with the embedded hole 533h of align unit lifting pulley 533a and 533b, and in the vertical direction rotates along with the rotation of align unit lifting pulley 533a and 533b to make the 3rd fulcrum 532.Align unit lifting pulley 533a and 533b is supported by first fulcrum 520 that aligns in the same manner as align unit 519.

Because the first alignment fulcrum 520 and align unit lifting pulley 533a and 533b are engaged by parallel pin (not shown), so align unit lifting pulley 533a and 533b aligns with first, fulcrum 520 synchronously rotates.

Here, the synchronous axial system of align unit lifting pulley 533a and 533b makes the 3rd fulcrum 532 move along the guide groove 521a in the vertical direction of slide unit 521, thus lifting align unit 519.Here, because the rotation of slide unit 521 limits, so only align unit 519 is elevated by the second alignment fulcrum 522.

As shown in Figure 7, driving band 535 is wound on align unit lifting pulley 533a and 533b and the second lifting pulley 534a and 534b.

Second lifting pulley 534a and 534b is located on each end of lifting transmitter shaft 536, and synchronously rotates along with the rotation of this lifting transmitter shaft 536.3rd lifting pulley 537 is located on lifting transmitter shaft 536, and driving band 538 is wound on the 3rd lifting pulley 537.Driving band 538 transmits the driving of align unit lifting motor M3.

Therefore, when align unit lifting motor M3 rotates, it drives and is delivered to driving band 538, the 3rd lifting pulley 537, lifting transmitter shaft 536, second lifting pulley 534a and 534b and driving band 535.

In addition, the driving of align unit lifting motor M3 passes to align unit 519 via driving band 535, align unit lifting pulley 533b and the 3rd fulcrum 532, makes paired align unit 519 synchronization lifting.

In this example embodiment, such as, align unit lifting motor M3, driving band 538, lifting transmitter shaft 536 and driving band 535 form mobile unit 550, and this mobile unit 550 is as make align unit 519 move to be positioned at can the mobile device of retreating position above aligned position (following) and lower distributing roller 514.

Align unit lifting HP sensor S3 is located near the align unit lifting pulley 533a on rear side.Align unit lifting HP sensor S3 this align unit 519 that detects when align unit 519 moves up as described below arrives lifting HP.

As shown in Figure 6A, align unit lifting pulley 533a comprises the flag portion 533f opened or closed for making align unit be elevated HP sensor S3.Such as, when paired align unit 519 is along with the rotation of align unit lifting pulley 533a and 533b during synchronization lifting, align unit lifting HP sensor S3 opens or closes, can detect and control the lifting position of align unit 519.

According to this structure, such as, when be shifted by every predetermined quantity sheet material broad ways and stacking classification stacking (offset stacked) and make sheet-stacking in lower tray 516 time, align unit 519 can on move to retreating position.In addition, when user takes out sheet material stacking in lower tray 516 after the end of job, align unit can on move to retreating position, easily sheet material can be taken out from lower tray 516.

When sheet-stacking, as in the top tray 515 of stack device and lower tray 516 each once on move to the position that sheet surface position can be detected, and to move down along with sheet-stacking.

Then, the lifting mechanism for making each lifting in top tray 515 and lower tray 516 is described.As shown in figs. 8 a and 8b, upper and lower pallet 515 and 516 has top tray drive motor M4 and lower tray drive motor M5 respectively, makes upper and lower pallet 515 and 516 separate and can certainly move by the vertical direction.Upper and lower supporter disk-drive motor M4 and M5 is all stepping motors.Top tray 515 and lower tray 516 are attached on the stand 571 that vertically arranges relative to the framework 570 of sheet-stacking apparatus 500.

Upper and lower supporter disk-drive motor M4 and M5 is all attached on substrate 572, and its pulley 573a be driven through on its motor shaft of pressure insertion utilizes timing belt 573 to pass to pulley 574.

Upper and lower supporter disk-drive motor M4 with M5 driving separately also passes to ratchet 576 by the axle 575 using parallel pin to be connected with pulley 574, and ratchet 576 uses parallel pin to be connected with pulley 574.Ratchet 576 is pushed to idle pulley 577 by spring (not shown).

Idle pulley 577 engages the driving of transmitting each motor M 4 and M5 with gear 578, and gear 578 engages the driving of transmitting each motor M 4 and M5 with the gear 579 on the one end being fixed on axle 580.The other end of axle 580 is provided with another gear 579 be fixed thereon, and the rotation of gear 579 passes to another gear 579 via axle 580.Therefore, each in upper and lower pallet 515 and 516 is driven in both sides, front and back.

In addition, this two gear 579 connects with stand 571 via gear 581.Here, each in upper and lower pallet 515 and 516 keeps level by making to set two rollers 582 to be on one side thereof positioned at the stand 571 doubled as roller receptor.

According to this structure, the driving of upper and lower supporter disk-drive motor M4 and M5 is passed, and upper and lower pallet 515 and 516 can be elevated along direction shown by arrow Z in Fig. 2 separately.

Upper and lower pallet 515 and 516 respectively with upper and lower supporter disk-drive motor M4 and M5, respective idle pulley 577, for supporting the substrate 572 of these parts, be attached to sheet material mounted panel (not shown) on this substrate 572 and other part integration, thus forms respective tray unit.

As shown in Figure 2, upper and lower supporter disc material Surface testing sensor S4 and S5 arranges the sheet surface (position, upper space) for detecting on upper and lower pallet 515 and 516 respectively.Upper and lower supporter disc material Surface testing sensor S4 and S5 is all the optical pickocff (not shown)s comprising luminescence unit and light receiving unit.

When detecting sheet surface, each position from below in upper and lower pallet 515 and 516 moves up.Initial position is the position that the upper surface of stacking sheet material or pallet 515 and 516 on upper and lower pallet 515 and 516 stops the light of upper and lower supporter disc material Surface testing sensor S4 and S5 respectively.

After moving to respective initial position, upper and lower pallet 515 and 516 moves down once.

Subsequently, sheet material is discharged in turn.When the upper surface of institute's stacking sheet material stops the light of upper and lower supporter disc material Surface testing sensor S4 or S5, corresponding top tray 515 or lower tray 516 move down until optical axis occurs.

Then, if take out sheet material from such as top tray 515 and lower tray 516, then this pallet moves to light by the initial position stopped.This operation repeats with the position of holding pallet.

In Fig. 9, detect the region residing for upper and lower pallet 515 and 516 respectively as the top tray region detection sensor S8 of detecting device and lower tray region detection sensor S9.Such as, the top tray region detection sensor S8 as detecting unit can detect as Figure 14 A, the region residing for top tray 515 shown in 14B and 14C.

Upper (lower) pallet area detecting sensor S8(S9) be fixed on the sensor attaching plate 587 of attaching on substrate 572.When upper and lower pallet 515 and 516 is elevated, upper and lower supporter disk area detecting sensor S8 and S9 is elevated respectively.

As pallet area detecting sensor S8(S9) when being elevated, the region flag 589 be attached on framework 570 switches pallet area detecting sensor S8(S9) switch.Thus, determinating area position.

In this example embodiment, be provided with multiple upper (lower) pallet area detecting sensor S8(S9), and region flag 589 is shaped as the number of sensors judging to open along with the lifting of upper and lower pallet 515 and 516.Thus, the number of sensors by opening judges the regional location of upper and lower pallet 515 and 516.

In Fig. 9, top tray motor clock detection sensor S10 and lower tray motor clock detection sensor S11 detects the clock of upper and lower supporter disk-drive motor M4 and M5 respectively.The position of upper and lower pallet 515 and 516 is respectively based on the infomation detection from upper and lower supporter coil motor clock detection sensor S10 and S11.

Upper and lower supporter coil motor clock detection sensor S10 and S11 calculates the clock of upper and lower supporter disk-drive motor M4 and M5 respectively by the respective flag portion detecting the rotation flag 588 be attached on the prolongation of gear 578.

In addition, as shown in Figure 10, upper and lower pallet 515 and 516 all has from its outstanding sheet material with or without detection flag 583.Sheet material detects with or without stacking sheet material with or without detection flag 583, and is attached on substrate 572 with or without check-out console 584 via sheet material.

Sheet material rotates around the direction of flag rotating shaft 585 along the R of arrow shown in Figure 10 indication with or without detection flag 583.Flag rotating shaft 585 and sheet material are riveted with or without check-out console 584.

When sheet material is not stacked in pallet such as top tray 515 and lower tray 516, sheet material draws by rotation spring 586 with or without detection flag 583 and gives prominence to from pallet.At this moment, corresponding with pallet top tray sheet material is in closed condition with or without detecting sensor S6 or lower tray sheet material with or without detecting sensor S7.As sheet material with or without detecting device upper and lower supporter disc material with or without detecting sensor S6 or S7 detect be attached to sheet material with or without on each pallet on check-out console 584 with or without stacking sheet material.

On the other hand, when sheet-stacking is in pallet such as top tray 515 and lower tray 516, sheet material rotates due to the weight of institute's stacking sheet material with or without detection flag 583.Upper and lower supporter disc material with or without detecting sensor S6 or S7 along with respective sheets is with or without detection moving down of flag 583 and become opening.That is, when sheet-stacking is on pallet, corresponding pallet sheet material becomes opening with or without detecting sensor from closed condition.

Figure 11 is the control block diagram of monochrome/color copy machine 100.Cpu circuit unit 630 comprises CPU629, read-only memory (ROM) (ROM) 631 and random-access memory (ram) 650.

Cpu circuit unit 630 controls image signal control unit 634, chopping machine control unit 635, sheet-stacking apparatus control unit 636 and external interface 637.Cpu circuit unit 630 according to the setting of the program be stored in ROM631 and operating unit 601 to control these unit.RAM650 is used as the region of such as interim retentive control data and controls the work area of correlation computations.

Chopping machine control unit 635 controls copying machine body 100A, and sheet-stacking apparatus control unit 636 controls sheet-stacking apparatus 500.External interface 637 is used as the interface with computing machine (Personal Computer (PC)) 620.Print data grid is turned to image by external interface 637, and this image is exported to image signal control unit 634.Graphicinformation is exported to chopping machine control unit 635 by image signal control unit 634.Graphicinformation is inputed to exposure control unit (not shown) by chopping machine control unit 635.

Figure 12 is the control block diagram of sheet-stacking apparatus control unit 636.This example embodiment describes sheet-stacking apparatus control unit 636 and is arranged on situation on sheet-stacking apparatus 500.But this example embodiment is not limited thereto situation.Such as, sheet-stacking apparatus control unit 636 by integrated with cpu circuit unit 630 and be located in copying machine body 100A, to control sheet-stacking apparatus 500 from copying machine body 100A.

Sheet-stacking apparatus control unit 636 comprises CPU701, RAM702, ROM703, input and output (I/O) unit 705, network interface 704 and communication interface 706.I/O unit 705 is relative to transmit control unit 707 and stackable unit control unit 708 input and output signal.

Stackable unit control unit 708 is connected with front and back align unit sliding motor M2 and M1, align unit lifting motor M3 and upper and lower supporter disk-drive motor M4 and M5.

In addition, front and back align unit HP sensor S2 with S1, align unit lifting HP sensor S3, upper and lower supporter disc material Surface testing sensor S4 with S5 and upper and lower supporter disc material are connected with stackable unit control unit 708 with S7 with or without detecting sensor S6.

In addition, upper and lower supporter disk area detecting sensor S8 is connected with stackable unit control unit 708 with S9 and upper and lower supporter coil motor clock detection sensor S10 with S11.Stackable unit control unit 708 is based on these motor M of signal control 1 to the M5 carrying out sensor S1 to S11.

In this example embodiment, stackable unit control unit 708 detects the region in from the bound position of top tray 515 to the area division of top tray sheet surface detecting sensor S4 residing for top tray 515.

The retreating position of align unit 519 is controlled based on testing result.In this example embodiment, control the clock quantity when driving align unit lifting motor M3, to control the retreating position of align unit 519.

Figure 13 is the diagram of circuit illustrating that the retreating position according to the align unit 519 of this example embodiment controls.

In step S801, when user selects the pattern of sheet-stacking in lower tray 516, sheet-stacking apparatus control unit 636 drives lower tray drive motor M5 and makes lower tray 516 is moved.If on the lower tray 516 of moving or stacking sheet material stop the light (step S802: yes) of lower tray sheet surface detecting sensor S5, so in step S803, sheet-stacking apparatus control unit 636 hold (judgements) top tray 515 now residing for region.

In this example embodiment, based on the position from the signal of top tray region detection sensor S8 and the signal determining top tray 515 from top tray motor clock detection sensor S10.

Then, align unit sliding motor M2 and M1 before and after sheet-stacking apparatus control unit 636 drives, and make align unit 519 perform initial operation and move to slip HP.Here, front and back align unit HP sensor S2 and S1 being located at front side and rear side is utilized to detect this slip of align unit 519 to slip HP respectively.

In step S804, detect after align unit 519 slides into slip HP at front and back align unit HP sensor S2 and S1, align unit sliding motor M2 and M1 before and after sheet-stacking apparatus control unit 636 drives, and make align unit 519 move to the broad ways aligned position of foundation sheets of sizes.The aligned position of align unit 519 is positioned at the position of the Width two ends preset distance apart from sheet material.

Subsequently, sheet-stacking apparatus control unit 636 drives align unit lifting motor M3, and align unit 519 is rotated and on move to lifting HP.In step S805, when align unit lifting HP sensor S3 detect align unit 519 arrive lifting HP time, sheet-stacking apparatus control unit 636 drives align unit lifting motor M3, and align unit 519 is displaced downwardly to can aligned position.

Can aligned position be the position that align unit 519 moves by broad ways to contact with sheet material after moving down.Thus, move to can after aligned position, align unit 519 broad ways moves to contact with sheet material, thus is alignd in sheet width direction.

According to the position of top tray 515, there is align unit 519 and move to the situation being elevated HP and making to interfere between this align unit 519 and top tray 515.In the case, in step S805, align unit 519 move to can aligned position and do not move to lifting HP.

In step S806, moving at align unit 519 can after aligned position, and sheet-stacking apparatus control unit 636 makes the transmission of sheet material start.In step S807, when the tail end of sheet material is by lower distributing roller 514 and when being stacked in lower tray 516, sheet-stacking apparatus control unit 636 makes to be positioned at and can the align unit 519 of aligned position slide according to sheets of sizes broad ways.Thus, the Width being stacked on the sheet material in lower tray 516 is aligned.

Repeat this operation until last sheet-stacking is in lower tray 516.

If last sheet material is stacked (step S808: yes) and alignment, then process advances to step S809.In step S809, sheet-stacking apparatus control unit 636 drives lower tray drive motor M5 and lower tray 516 is moved down, to be confirmed sheet surface position when the light of lower tray sheet surface detecting sensor S5 stops.

If the light of lower tray sheet surface detecting sensor S5 is through (step S810: yes), then in step S811, sheet-stacking apparatus control unit 636 makes lower tray 516 is moved.If on the lower tray 516 of moving or stacking sheet material stop the light (step S812: yes) of lower tray sheet surface detecting sensor S5, the region that top tray 515 that then in step S813, sheet-stacking apparatus control unit 636 is held again (again judging) is now residing.

Perform this process be because when lower tray 516 will on move time there is the situation of the position movement of this lower tray 516.Such as, when top tray sheet material to detect in top tray 515 without sheet material with or without detecting sensor S6, can judge that this top tray 515 is in upper limit position.In the case, align unit 519 keeps out of the way (above moving) to initial position.

Sheet-stacking apparatus control unit 636 is based on the retreating position of result of determination control align unit 519 when restarting sheet-stacking or take out sheet material of the regional location of top tray 515.

Such as, if top tray 515 is positioned at the upper limit position (step S815: yes) above the E1 of region as shown in Figure 14 A, then in step S831, sheet-stacking apparatus control unit 636 makes align unit 519 keep out of the way initial position as retreating position shown in (above moving) to Figure 14 A.

If top tray 515 not to be positioned at above the E1 of region (step S815: no) and this top tray 515 (step S832: yes) between region E1 as shown in Figure 14B and region E2, then in step S833, sheet-stacking apparatus control unit 636 makes align unit 519 retreat to the middle retreating position shown in Figure 14 B.

If top tray 515 not to be positioned at above the E1 of region (step S815: no) as shown in Figure 14 C and this top tray 515 is positioned at region E2 and E3(lower position, region) between (step S832: no), then in step S834, sheet-stacking apparatus control unit 636 makes align unit 519 retreat to the lower limit retreating position shown in Figure 14 B.

Therefore, change the retreating position of align unit 519 according to the position of top tray 515 how the position of no matter top tray 515 can both to be reduced between top tray 515 and align unit 519 interfere.Even if when taking out sheet material from lower tray 516, align unit 519 also can on move to the position corresponding with the position of top tray 515, thus improve the taken out performance of sheet material.

On the other hand, when sheet-stacking is in top tray 515, this top tray 515 moves down along with the quantity increase of institute's stacking sheet material.When sheet material is discharged in top tray 515, top tray alignment unit 517 limits the width position of sheet material.

The align unit 519 of lower tray alignment unit 518 now retreats to the initial position such as shown in Fig. 2.Then, sheet material P is by stacking in turn.The position that this of sheet material P is stacking to be caused top tray 515 to be displaced downwardly to align unit 519 as shown in fig. 15 being pushed, this top tray 515 contacts from top with align unit 519 thus.

Align unit 519 is supported, can rotate around the first alignment fulcrum 520, this align unit 519 to be moved down by the first alignment fulcrum 520 and the 3rd fulcrum 532.

Thus, when top tray 515 moves down further, align unit 519 as Figure 15 B and 15C be shown in by top tray 515 push while move down.That is, when sheet material P is stacked in top tray 515, the moving down of this top tray 515 makes align unit 519 move down and without the need to driving align unit lifting motor M3.

Therefore, the lower tray alignment unit 518 being stacked on the width position of sheet material in lower tray 516 for alignment is in turn located between liftable upper and lower pallet 515 and 516, thus stably stacking a large amount of sheet material.

That is, lower tray alignment unit 518 is located between multiple sheet-stacking unit, and in turn alignment be stacked in multiple sheet-stacking unit below sheet-stacking unit on the width position of sheet material, thus stably stacking a large amount of sheet material.In this example embodiment, even if a large amount of curling sheet-stackings is in the heap tray of below, also can reduce due to stacking sheet material tilt cause can stacking performance worsen.

In addition, the retreating position of align unit 519 changes according to the position of top tray 515, thus can prevent align unit 519 from contacting with top tray 515 when upper moving.

In addition, even if when taking out the sheet material in lower tray 516, align unit 519 also can on move to the position corresponding with the position of top tray 515, thus improve sheet material taking-out energy.

In this example embodiment, based on the position from the signal of top tray region detection sensor S8 and the signal determining top tray 515 from top tray motor clock detection sensor S10.

But, such as, when top tray sheet material to detect in top tray 515 without sheet material with or without detecting sensor S6, can judge that top tray 515 is in upper limit position.In the case, align unit 519 retreats to initial position with its maximum upwards amount of keeping out of the way (amount of movement).Therefore, the retreating position of align unit 519 can be controlled with or without the testing result of detecting sensor S6 based on top tray sheet material.

To the align unit 519 when taking out the sheet material being discharged and being stacked in lower tray 516 moves to the retreating position corresponding with the position of top tray 515 in case improve sheet material desirable go out the situation of performance be illustrated.But, the present invention is not limited thereto.

Such as, when taking out the sheet material be discharged in lower tray 516, lower tray 516 can move down to increase the space moved between the align unit 519 of the retreating position corresponding with the position of top tray 515 and this lower tray 516, thus improve sheet material desirable go out performance.

Present explanation the second example embodiment of the present invention.In second example embodiment, lower tray 516 moves down when taking out the sheet material of discharging.Figure 16 is the diagram of circuit represented according to the retreating position control of the align unit 5119 of this example embodiment and the position control of lower tray 516.

In step S817, when user selects the pattern of sheet-stacking in lower tray 516, sheet-stacking apparatus control unit 636 drives lower tray drive motor M5 and makes lower tray 516 is moved.If on the lower tray 516 of moving or stacking sheet material stop the light (step S818: yes) of lower tray sheet surface detecting sensor S5, then sheet-stacking apparatus control unit 636 hold (judgements) top tray 515 now residing for region.

Then, align unit sliding motor M2 and M1 before and after sheet-stacking apparatus control unit 636 drives, and make align unit 519 perform initial operation and move to slip HP.Here, front and back align unit HP sensor S2 and S1 being located at front side and rear side is utilized to detect this slip of align unit 519 to slip HP respectively.

In step S820, detect after align unit 519 slides into slip HP at front and back align unit HP sensor S2 and S1, align unit sliding motor M2 and M1 before and after sheet-stacking apparatus control unit 636 drives, and make align unit 519 move to the aligned position of foundation sheets of sizes.

Subsequently, sheet-stacking apparatus control unit 636 drives align unit lifting motor M3, and align unit 519 is rotated and on move to lifting HP.In step S821, when align unit lifting HP sensor S3 detect align unit 519 arrive lifting HP time, sheet-stacking apparatus control unit 636 drives align unit lifting motor M3, and align unit 519 is displaced downwardly to can aligned position.

According to the position of top tray 515, there is align unit 519 and move to the situation being elevated HP and making to interfere between this align unit 519 and top tray 515.In the case, in step S821, align unit 519 move to can aligned position and do not move to lifting HP.

In step S822, moving at align unit 519 can after aligned position, and sheet-stacking apparatus control unit 636 makes the transmission of sheet material start.In step S825, when the tail end of sheet material is by lower distributing roller 514 and when being stacked in lower tray 516, sheet-stacking apparatus control unit 636 makes to be positioned at and can the align unit 519 of aligned position slide according to sheets of sizes broad ways.Thus, the Width being stacked on the sheet material in lower tray 516 is aligned.

Repeat this operation until last sheet-stacking is in lower tray 516.

If last sheet material is stacked (step S826: yes) and alignment, then process advances to step S827.In step S827, when the light of lower tray sheet surface detecting sensor S5 is stopped, sheet-stacking apparatus control unit 636 drives lower tray drive motor M5 and lower tray 516 is moved down.If the light of lower tray sheet surface detecting sensor S5 is through (step S828: yes), then in step S829, sheet-stacking apparatus control unit 636 makes lower tray 516 move down scheduled volume.In step S830, sheet-stacking apparatus control unit 636 stops the movement of lower tray 516.

Figure 17 A and 17B is the diagram representing the position of lower tray 516 in this moves down.Figure 17 A represents that sheet material P is stacked in the state in lower tray 516 while being aligned.When this end of job, lower tray 516 moves down scheduled volume L as seen in this fig. 17b from the state that the light of lower tray sheet surface detecting sensor S5 is through.

Lower tray 516 moves down scheduled volume L after the end of job, makes the sheet material P in align unit 519 and lower tray 516 have the position relationship do not interfered between the two.Therefore, it is possible to improve the taken out performance of the sheet material P in lower tray 516.

Scheduled volume L is adopted in this example embodiment.But, when lower tray 516 moves down after the end of job, the downward amount X shown in Figure 18 A and 18B can be adopted.Downward amount X can change according to the retreating position of the align unit 519 corresponding with the position of top tray 515.

Such as, when the retreating position of align unit 519 is lower than lifting HP, the downward amount X of lower tray 516 can increase this measures of dispersion.The downward amount X of lower tray 516 can change, no matter thus how the retreating position of align unit 519 all guarantees that certain sheet material can take out performance according to the retreating position of align unit 519.

The example having comprised two (multiple) pallets 515 and 516 relative to sheet-stacking apparatus 500 is illustrated example embodiment.But this example embodiment also can be applicable to the sheet-stacking apparatus comprising three or more pallet (sheet-stacking unit).

Although reference example embodiment is to present disclosure has been explanation, is understood that and the invention is not restricted to disclosed example embodiment.The scope of following claims should be consistent with the widest explanation, to contain all modification, equivalent structure and function.

Claims (7)

1. structure is in order to a sheet-stacking apparatus for stacking sheet material, and described sheet-stacking apparatus comprises:

Multiple eduction gear, vertically arranges and constructs in order to discharge sheet material;

Multiple sheet material stacking apparatus, corresponding respectively to described multiple eduction gear can be elevated independently, and structure is in order to sheet material of discharging from described eduction gear stacking on described multiple sheet material stacking apparatus;

Aligning apparatus, is located between described multiple sheet material stacking apparatus, and structure is in order to make to be discharged to the aligned in position of the sheet material on the below sheet material stacking apparatus in described multiple sheet material stacking apparatus at the Width perpendicular with discharge direction; And

Control setup, constructs to control described aligning apparatus,

Wherein, described aligning apparatus comprises:

Align unit, constructs in order to move along described Width, and makes to be stacked on the aligned in position of the sheet material on the sheet material stacking apparatus of described below at described Width; And

Mobile device, constructing can aligned position in order to make described align unit be moved downward to when described sheet material is aligned, and after described sheet material is aligned, make described align unit can move up by aligned position from described, described can aligned position, along the movement of described Width, described sheet material is alignd by described align unit, and

Wherein, when taking out the sheet material be stacked on the sheet material stacking apparatus of described below, described control setup controls described mobile device, with make described align unit move to described can retreating position above aligned position, and change described retreating position according to the position of top sheet material stacking apparatus, do not contact with described top sheet material stacking apparatus to make described align unit.

2. sheet-stacking apparatus according to claim 1, also comprises:

Detecting device, constructs the position of the top sheet material stacking apparatus detected in described multiple sheet material stacking apparatus, is provided with described aligning apparatus between described top sheet material stacking apparatus and described below sheet material stacking apparatus.

3. sheet-stacking apparatus according to claim 1, also comprises:

Sheet material, with or without detecting device, constructs to detect with or without stacking sheet material on the sheet material stacking apparatus of described top,

Wherein, when described sheet material to detect with or without detecting device described top sheet material stacking apparatus there is no stacking sheet material time, described control setup controls described mobile device and makes the amount of moving up of described align unit maximum.

4. sheet-stacking apparatus according to claim 1, wherein, sheet material stacking apparatus moves down and after contacting with the described align unit moving to described retreating position above described, described control setup controls described top sheet material stacking apparatus and described mobile device, and described top sheet material stacking apparatus is moved down together with described align unit.

5. sheet-stacking apparatus according to claim 1, wherein, when taking out the sheet material be stacked on the sheet material stacking apparatus of described below, described control setup controls described below sheet material stacking apparatus, and described below sheet material stacking apparatus is moved down.

6. sheet-stacking apparatus according to claim 5, wherein, when described below sheet material stacking apparatus moves down, described control setup controls described below sheet material stacking apparatus, makes described below sheet material stacking apparatus be moved downward to position according to described align unit position.

7. an imaging device, comprising:

Imaging device, constructs in order to imaging on sheet material; And

According to described sheet-stacking apparatus arbitrary in claim 1 to 6, construct in order to the stacking sheet material utilizing the imaging thereon of described imaging device.